Communication pubs.acs.org/bc
Tyrosine-Selective Functionalization for Bio-Orthogonal CrossLinking of Engineered Protein Hydrogels Christopher M. Madl† and Sarah C. Heilshorn*,‡ †
Department of Bioengineering and ‡Department of Materials Science and Engineering, Stanford University, Stanford, California 94305, United States S Supporting Information *
ABSTRACT: Engineered protein hydrogels have shown promise as artificial extracellular matrix materials for the 3D culture of stem cells due to the ability to decouple hydrogel biochemistry and mechanics. The modular design of these proteins allows for incorporation of various bioactive sequences to regulate cellular behavior. However, the chemistry used to cross-link the proteins into hydrogels can limit what bioactive sequences can be incorporated, in order to prevent nonspecific cross-linking within the bioactive region. Bio-orthogonal cross-linking chemistries may allow for the incorporation of any arbitrary bioactive sequence, but site-selective and scalable incorporation of bio-orthogonal reactive groups such as azides that do not rely on commonly used amine-reactive chemistry is often challenging. In response, we have optimized the reaction of an azide-bearing 4-phenyl1,2,4-triazoline-3,5-dione (PTAD) with engineered elastin-like proteins (ELPs) to selectively azide-functionalize tyrosine residues within the proteins. The PTAD-azide functionalized ELPs cross-link with bicyclononyne (BCN) functionalized ELPs via the strain-promoted azide−alkyne cycloaddition (SPAAC) reaction to form hydrogels. Human mesenchymal stem cells and murine neural progenitor cells encapsulated within these hydrogels remain highly viable and maintain their phenotypes in culture. Tyrosine-specific modification may expand the number of bioactive sequences that can be designed into protein-engineered materials by permitting incorporation of lysine-containing sequences without concern for nonspecific cross-linking.
H
engineering has been employed to generate hydrogels with the precise control over material chemistry afforded by synthetics and the cell-interactive properties of many naturally derived materials.9 Elastin-like proteins (ELPs) are a class of protein-engineered materials that are well-suited for use as cell-encapsulating hydrogels. ELPs can be designed as modular proteins that consist of alternating elastin-like and variable domains.10 The elastin-like domain is based on the elastin-like VPGXG motif and confers elastic mechanical properties on hydrogels prepared from these materials.11 The guest “X” residue can be any amino acid other than proline, permitting incorporation of various chemical functionalities to this domain, such as primary amines via lysine residues to facilitate cross-linking.12 The variable domain facilitates incorporation of bioactive sequences to regulate cellular behaviors such as adhesion and matrix degradation.10,13 A significant advantage of the modular design of ELPs is the ability to decouple tuning of matrix stiffness from access to bioactive cues by restricting cross-
ydrogels are commonly used as cell-encapsulating materials to study cell−matrix interactions and to serve
Scheme 1. PTAD Oxidation
as scaffolds for tissue engineering applications.1−3 A variety of synthetic and naturally derived materials are routinely employed to generate cell-encapsulating gels, such as poly(ethylene glycol) (PEG), collagen, and alginate.1 While these materials are highly cell-compatible, each has potential drawbacks. Synthetics like PEG are bioinert and must be further functionalized with bioactive molecules to permit cellular behaviors such as spreading and migration.4−6 On the other hand, collagen is naturally cell-adhesive and degradable, but can suffer from batch-to-batch variability and exhibits limited tuning of mechanical properties.7,8 To overcome these limitations of commonly used hydrogel materials, protein © 2017 American Chemical Society
Special Issue: Peptide Conjugates for Biological Applications Received: December 14, 2016 Revised: January 18, 2017 Published: February 2, 2017 724
DOI: 10.1021/acs.bioconjchem.6b00720 Bioconjugate Chem. 2017, 28, 724−730
Communication
Bioconjugate Chemistry
Figure 1. PTAD-N3 functionalization of ELP for bio-orthogonal cross-linking. (A) Modification of ELP tyrosine residues with PTAD (structure 2). (B) Modification of cell-adhesive RGD-ELP with BCN. (C) Mixing PTAD-ELP with BCN-ELP results in bio-orthogonal cross-linking via the SPAAC reaction.
We recently reported the design of elastin-like protein hydrogels that cross-link via the bio-orthogonal strainpromoted azide−alkyne cycloaddition (SPAAC) reaction.17 Due to the bio-orthogonal nature of the cross-linking reaction, gelation of these materials is highly specific, resulting in high viability and phenotypic maintenance of encapsulated cells.17 This bio-orthogonality also provides the possibility of designing the bioactive site to contain any arbitrary amino acid sequence, because the cross-linking reaction will not interfere with any naturally occurring functional groups. However, the ELPs still must be functionalized with the azide and bicyclononyne (BCN) reaction partners post-expression. In our previous system, this was accomplished by diazo transfer or Nhydroxysuccinamide (NHS) ester-mediated reactions with primary amines on lysine residues within the elastin-like domain to produce azide- or BCN-modified ELPs, respectively. Thus, the initial versions of these bio-orthogonally cross-linked materials still rely on amine-reactive chemistry and would prevent the implementation of lysine-containing bioactive sequences.
linking sites to the elastin-like domain. However, in versions of ELP that rely on amine-reactive cross-linkers to form hydrogel networks, the variable domain is precluded from containing any lysine residues, or else cross-links will form at the bioactive site and potentially block the ability of the cells to interact with this domain. Common bioactive motifs, including the lamininderived, cell-adhesive sequence IKVAV,14 the vascular endothelial growth factor mimicking QK peptide (LTWQELYQLKYKGI),15 and the bone morphogenetic protein-2 mimicking knuckle epitope peptide (KIPKASSVPTELSAISTLYL),16 contain lysines and could thus not be incorporated into ELP hydrogels generated using existing amine-reactive chemistries. One potential strategy would be to take advantage of sulfhydryl-based chemistries using cysteine residues engineered into the proteins. However, the ability of the cysteinecontaining proteins to cross-link via disulfide bridge formation makes purifying and manipulating such proteins difficult. An alternative strategy would be to use cross-linking chemistries that are not found in biological systems, thereby permitting incorporation of an arbitrary bioactive sequence into the variable domain of the proteins. 725
DOI: 10.1021/acs.bioconjchem.6b00720 Bioconjugate Chem. 2017, 28, 724−730
Communication
Bioconjugate Chemistry
To demonstrate selective azide incorporation without lysine modification, we reacted tyrosine residues found within the variable region of a nonbioactive ELP with PTAD 2 (Figure 1A). Barbas and colleagues previously demonstrated that the use of Tris buffers in the PTAD modification reaction limited the nonspecific reaction of an isocyanate decomposition product of the oxidized PTAD with primary amines on the proteins.19 Thus, we first chose to run the ELP modification reaction in 50 mM Tris buffer (pH 7.5). However, addition of PTAD 2 to a solution of ELP in Tris buffer resulted in precipitation of the protein from solution. In order to maintain the solubility of the ELP during the PTAD reaction, a mixed solvent system consisting of a 1:1 volumetric mixture of 50 mM Tris buffer and DMF was used. The ELP remained soluble throughout the reaction following the addition of PTAD 2 at molar ratios from 1:1 to 4:1 PTAD:tyrosine. The extent of tyrosine modification was assessed using 1H NMR (Figure 2, Figure S1). A 4-fold excess of PTAD relative to tyrosine resulted in modification of ∼60% of tyrosine residues (Table 1). Work by Barbas and colleagues also demonstrated that PTAD modification was most efficient in phosphate buffers,18 so we additionally ran the reaction in 100 mM phosphate buffer (pH 8.0) and a 1:1 volumetric mixture of 100 mM phosphate buffer and DMF. As with the pure Tris buffer, the pure phosphate buffer also resulted in ELP precipitation, while the mixed phosphate/DMF system maintained ELP solubility throughout the reaction. Using the mixed solvent system, a 4fold excess of PTAD resulted in a modification of ∼80% of tyrosine residues, which was a noticeable improvement over the Tris buffered condition (Table 1). This increase in reaction efficiency was not due to pH differences between the two buffers employed by Barbas and colleagues in their previous studies,18,19 as there was no difference in tyrosine functionalization when the PTAD reaction was run at pH 7.5 versus pH 8.0 in a phosphate buffered system (Table S1). While the phosphate buffer/DMF solvent mixture improved the efficiency of tyrosine functionalization, the removal of the Tris buffer may increase undesired side reactions with primary amines present in the protein. To assess the extent of crossreactivity with primary amines, the presence of free amines post-modification was measured via the 2,4,6-trinitrobenzenesulfonic acid (TNBSA) assay.20 Consistent with previously published results,18 PTAD modification in Tris-buffered systems resulted in no significant decrease in the number of free amines per ELP polymer (Figure 3A). However, carrying out the PTAD modification reaction in mixed phosphate buffer/DMF resulted in a ∼22% decrease in the number of free amines per ELP. We hypothesized that this was likely due to reaction of an isocyanate decomposition product of the activated PTAD with primary amines in the ELP (Figure 3B).19 The evolution of gas observed upon addition of PTAD 2 to the reaction mixture is consistent with decomposition of the PTAD into an amine-reactive isocyanate species.19 1H NMR confirmed that PTAD modification in phosphate buffer/DMF exhibited nonspecific reaction with the primary amines of the lysine residues present in the ELP (Figure 3C). Thus, while the phosphate buffer/DMF system facilitated reasonably high tyrosine modification efficiency, it also permitted significant side reactions with primary amines, limiting the utility of this procedure in selective tyrosine functionalization. To optimize both tyrosine functionalization efficiency and selectivity in a single system, we considered the use of polar aprotic solvents other than DMF in the reaction mixture.
Figure 2. 1H NMR to confirm PTAD functionalization of ELP tyrosines. 1H NMR spectra of (A) unmodified ELP and (B) PTADfunctionalized ELP.
Table 1. Optimizing PTAD Modification of ELP
a
buffer
solvent
molar ratio PTAD:tyrosine
Tris Tris Tris Tris Phosphate Phosphate Phosphate Phosphate Phosphate
-DMF DMF DMF -DMF MeCN MeCN MeCN
4:1 1:1 2:1 4:1 4:1 4:1 1:1 2:1 4:1
% tyrosine conversion
modified tyrosines/ELP
a
a
36% 54% 62%
1.5 2.1 2.5
a
a
81% 25% 60% 89%
3.2 1.0 2.4 3.5
Insoluble precipitate formed during PTAD modification reaction.
In order to design a system that would permit the incorporation of lysine-containing bioactive sequences in the variable domain of the ELPs, we sought to employ a chemistry that will specifically functionalize tyrosine residues with azide moieties. Previously, Barbas and colleagues demonstrated selective tyrosine modification via an ene-type reaction using 4-phenyl-3H-1,2,4-triazoline-3,5(4H)-diones (PTADs).18,19 Here, we employ a commercially available, azide-bearing PTAD, 4-(4-(2-azidoethoxy)phenyl)-1,2,4-triazolidine-3,5dione (1), to functionalize tyrosine residues in ELPs with azides for SPAAC-mediated cross-linking into hydrogels. Oxidation of 1 with 1,3-dibromo-5,5-dimethylhydantoin affords activated PTAD 2 (Scheme 1), which can participate in enetype reactions with tyrosine side chains.19 726
DOI: 10.1021/acs.bioconjchem.6b00720 Bioconjugate Chem. 2017, 28, 724−730
Communication
Bioconjugate Chemistry
Figure 3. Optimizing solvent conditions to minimize lysine cross-reactivity. (A) Quantification of free amines present on ELPs following PTAD reaction under various solvent conditions. Only reaction in phosphate buffer/DMF exhibited significant cross-reactivity with amines present on the ELPs. **p < 0.01 relative to unmodified ELP, one-way ANOVA with Bonferroni post-hoc test. (B) Decomposition of PTAD 2 can generate a reactive isocyanate moiety that reacts with primary amines present on lysines in the ELP sequence. (C) 1H NMR spectra reveal significant lysine modification following PTAD reaction in phosphate buffer/DMF, but only minimal lysine modification in phosphate buffer/acetonitrile.
Barbas and colleagues previously reported successful PTAD functionalization in phosphate buffer/acetonitrile (MeCN) mixtures.18 ELP was dissolved in a 1:1 volumetric mixture of 100 mM phosphate buffer and acetonitrile, and PTAD 2 was added to a solution of ELP at molar ratios from 1:1 to 4:1 PTAD:tyrosine. A 4:1 PTAD:Tyr ratio resulted in ∼90% modification of the tyrosine residues present in the ELP, an improvement relative to the phosphate buffer/DMF system (Table 1). Furthermore, the phosphate buffer/acetonitrile system was significantly more selective for tyrosines over primary amines. No difference in the number of free amines per ELP polymer relative to unmodified ELP was detected by TNBSA assay following PTAD reaction in phosphate buffer/ acetonitrile (Figure 3A). Furthermore, 1H NMR suggested that the large majority of lysine residue primary amines remain unreacted post-PTAD functionalization (Figure 3C). Noticeably less gas evolution was observed in the phosphate/ acetonitrile system, suggesting that PTAD decomposition was less prevalent under these reaction conditions. Using PTADmodified ELPs produced by the optimized reaction conditions, the presence of azide groups in the PTAD-modified ELP for use in SPAAC-mediated cross-linking was confirmed by FT-IR (Figure S2). These results indicate that PTAD-functionalization
in mixed phosphate buffer/acetonitrile is an effective route for selective introduction of azides via tyrosine residues. In order to facilitate SPAAC-mediated cross-linking of ELPs into hydrogels, a second ELP component functionalized with BCN was prepared by reacting ELP with BCN-NHS, based on our previously published procedure17 (Figure 1B,C). The molar ratio of BCN:ELP was varied to afford an average of three lysine residues functionalized with BCN per ELP polymer.17 To permit cell adhesion and spreading within the gels, the variable region within the BCN-modified ELP was designed to contain an extended RGD integrin-binding sequence derived from human fibronectin.10 Azide-PTAD-functionalized ELP and BCN-functionalized RGD-ELP were separately dissolved in phosphate-buffered saline (PBS) to a concentration of 5% (w/ v). Upon mixing in a 1:1 volumetric ratio, gelation occurs within seconds, and the resulting gels reach their plateau modulus within minutes (τ1/2
